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多年冻土地区铁路路基的振动与环境变化对路基稳定性的影响问题日益突出,为了评价这种影响引起的青藏铁路多年冻土区冻土的变化状况,首次应用了一种简便、高效、环保的瞬态面波勘探方法对其天然地表和典型结构路基及其下部多年冻土层进行了勘探。试验数据良好、频散特征显著,通过反演分析得到了青藏高原多年冻土地区天然地表和典型结构路基下部土体的剪切波速度剖面和多年冻土的分布。勘探结果表明,青藏铁路北麓河试验段勘探区内多年冻土上限一般为2 m,层厚为20 m左右,多年冻土层Vs平均为600 m/s以上。该结果与该区地质钻探编录和钻孔波速测试结果较为一致,说明瞬态面波勘探在自然环境严峻的青藏高原多年冻土地区有着良好的适用性。 相似文献
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Three-dimensional simulation of track on poroelastic half-space vibrations due to a moving point load 总被引:1,自引:0,他引:1
An analytical approach is used to investigate dynamic responses of a track system and the poroelastic half-space soil medium subjected to a moving point load under three-dimensional condition. The whole system is divided into two separately formulated substructures, the track sub-system and the ground. The ballast supporting rails and sleepers is placed on the surface of the ground. The rail is modeled by introducing the Green function for an infinitely long Euler beam subjected to the action of the moving point load and the reaction of sleepers represented by a continuous mass. Using the double Fourier transform, the governing equations of motion are then solved analytically in the frequency–wave-number domain. The time domain responses are evaluated by the inverse Fourier transform computation for a certain load velocities. Computed results show that dynamic responses of the soil medium are considerably affected by the fluid phase as well as the load velocity. 相似文献
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Permafrost along the Qinghai-Tibet Railroad produces the great change under the
influence of climate change, such as the decreasing of permafrost table, the rising of permafrost temperatures, etc. Climate effect on permafrost is the long-term process. Engineering action makes rapidly permafrost the large extent change. On the basis of analyzing the permafrost change under the climate change and engineering action, the thermal regime and spatial distribution of permafrost are predicted for air temperature rising 1℃ and 2℃ after 50 years in this paper. The results show that climate change results in the larger change for the thermal regime and spatial distribution of permafrost. Permafrost change will produce the great effect on the Qinghai-Tibet Railroad engineering, not only resulting in the decreasing of permafrost table beneath the roadbed, but also resulting in thawing settlement due to the thawing of ground ice near permafrost table. The idea of cooling roadbed and active protecting permafrost for the Qinghai-Tibet Railroad engineering could adjust and control the permafrost thermal state, some better methods are provided to ensure the engineering stability in the areas of warm permafrost and high ice content. 相似文献
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洛湛铁路D1K41+300~84585段路基上部土层松散,下部岩体(石灰岩)溶洞发育,根据工程地质水文地质情况,确定注浆参数和注浆方式,在土体和岩体中通过不同的浆液注浆,固结、充填松散的土层和岩体中的溶蚀、溶洞、溶槽等,使之形成完整的固结体,从而加强岩溶路基的承载力,确保铁路正常运营。介绍了注浆施工工艺及注浆效果。 相似文献
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The operation of a railway track in cold regions results in the premature deformation of subgrade soils caused by significant temperature fluctuations and ecological imbalance. Identification and calculation of the thawing degree of permafrost soils, frost heaving of clays, and groundwater flooding require careful engineering and geological surveying. The paper describes the unique, long-standing experience of the university scientists connected with maintaining the Russian East-Siberian and Trans-Baikal Railways'' facilities. Specific features of and requirements for the surveying, depending on the geological and climatic conditions, are identified. 相似文献
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应用冷却路基原理建设青藏铁路 总被引:9,自引:6,他引:3
More than half of the total length of the Qinghai-Tibet Railroad (QTR) traverses warm (0 to-1℃) permafrost areas, and about 40% of its total length is in ice-rich permafrost areas. Thc construction of the QTR also must consider the impacts of climatic warming along the QTR during the next 50~100 years. The latest projection indicates a warming of 2.2 to 2.6℃ on the Qinghai-Tibet Plateau (QTP) by the year 2050. Therefore, the key to the successful construction of the QTR is to protect permafrost from being thawed. Although railroad construction in permafrost areas has had a history of more than 100 years, the troubled sections of the railroads in permafrost areas have been greater than 30% of their total length. Based on the experiences and lessons learned from the road construction in permafrost areas, both in China and abroad, the author proposes that the principle of “active cooling” of railroad roadbed by lowering permafrost temperatures should be used in designing QTR, rather than that of “passive protection” of permafrost through increasing thermal resistance of roadway, such as increasing fill thickness and/or using insulative materials. This is especially important for the road sections in warm, ice-rich permafrost. In addition, this paper proposes several methods for “cooling the roadbcd” by controlling radiation, convection and conduction through modifying roadway structure and using different fill materials. 相似文献
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V. G. Kondratiev 《寒旱区科学》2013,5(4):0377-0386
The history of railway and highway construction in permafrost zones in Russia, the United States, Canada, and China spans more
than 110 years. Nonetheless, no railway track or highway has yet been built in such area that is impervious to deformation caused
by subsidence resulting from the thawing of ice-rich subgrade soils. This paper presents data on the roadbed states of the Transbaikalian
and the Baikal-Amur Railways as well as the Russian "AMUR" Chita-Khabarovsk Highway. It also discusses the feasibility
of roadbed stability maintenance using methods based on the reduction of the mean annual ground temperature and roadbed
preservation in a permafrost state by means of the natural cooling and heating factors ratio regulation resulting in a reduction of the
heat generation in the roadbed and the adjoining area accompanied by an increase of heat consumption with help of the
sun-precipitation protective sheds (awnings), rock covers, dolomite powder (reflective paint), cooling tube and thermosyphons as
well as tower supports and corrugated pipe culverts stability. 相似文献
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